EP3839372A1 - Agencement de collecteurs géothermiques pour grandes installations dans l'utilisation de froid urbain - Google Patents

Agencement de collecteurs géothermiques pour grandes installations dans l'utilisation de froid urbain Download PDF

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Publication number
EP3839372A1
EP3839372A1 EP19218755.7A EP19218755A EP3839372A1 EP 3839372 A1 EP3839372 A1 EP 3839372A1 EP 19218755 A EP19218755 A EP 19218755A EP 3839372 A1 EP3839372 A1 EP 3839372A1
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EP
European Patent Office
Prior art keywords
flow
return
common
collectors
ground
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EP19218755.7A
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German (de)
English (en)
Inventor
Johann Harry Steinhäuser
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Steinhaeuser & Co KG GmbH
Steinhaeuser & Co KG GmbH
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Steinhaeuser & Co KG GmbH
Steinhaeuser & Co KG GmbH
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Priority to EP19218755.7A priority Critical patent/EP3839372A1/fr
Publication of EP3839372A1 publication Critical patent/EP3839372A1/fr
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    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F24HEATING; RANGES; VENTILATING
    • F24TGEOTHERMAL COLLECTORS; GEOTHERMAL SYSTEMS
    • F24T10/00Geothermal collectors
    • F24T10/10Geothermal collectors with circulation of working fluids through underground channels, the working fluids not coming into direct contact with the ground
    • F24T10/13Geothermal collectors with circulation of working fluids through underground channels, the working fluids not coming into direct contact with the ground using tube assemblies suitable for insertion into boreholes in the ground, e.g. geothermal probes
    • F24T10/15Geothermal collectors with circulation of working fluids through underground channels, the working fluids not coming into direct contact with the ground using tube assemblies suitable for insertion into boreholes in the ground, e.g. geothermal probes using bent tubes; using tubes assembled with connectors or with return headers
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02BCLIMATE CHANGE MITIGATION TECHNOLOGIES RELATED TO BUILDINGS, e.g. HOUSING, HOUSE APPLIANCES OR RELATED END-USER APPLICATIONS
    • Y02B10/00Integration of renewable energy sources in buildings
    • Y02B10/40Geothermal heat-pumps
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02EREDUCTION OF GREENHOUSE GAS [GHG] EMISSIONS, RELATED TO ENERGY GENERATION, TRANSMISSION OR DISTRIBUTION
    • Y02E10/00Energy generation through renewable energy sources
    • Y02E10/10Geothermal energy

Definitions

  • the invention relates to an arrangement of geothermal collectors for large systems in the cold use of local heating.
  • geothermal collectors With geothermal heating using geothermal collectors (geothermal collectors), heat is extracted from the ground using geothermal collectors, which is raised to a higher temperature level by a heat pump so that it can be used to heat a building or other facility.
  • Geothermal collectors extract seasonally stored energy from the subsurface up to a depth of approx. 5 m (VDI 4640 Part 2, 2015).
  • the heat brought into the ground from the environment, in particular from rain, outside air and sun is transferred to the heat transfer medium in the ground collectors and is transported by the heat transfer medium to the heat pump.
  • the near-surface geothermal energy can also be used for passive cooling or, with a reversible heat pump, even for active cooling.
  • Ground collectors essentially consist of a pipe with a mostly loop-shaped, spiral-shaped or meander-shaped course, which is usually laid at a depth of 1 to 1.5 m below the surface of the earth, in special cases even deeper. At these depths, temperatures of 2 to 5 ° C and in August of 12 to 15 ° C are present at the beginning of February with undisturbed soil conditions.
  • a mixture of water and antifreeze e.g. glycol
  • geothermal heating is also known as "cold use of local heat" if several buildings are supplied via this system from one or more common collector system (s) and a distribution network. If only one building is supplied, it is a question of conventional geothermal energy use.
  • geothermal collectors are required for geothermal heating of several residential units in one, two, terraced and multi-family houses or entire settlements. Because of the good heat transfer, arrangements of geothermal collectors for large-scale systems are preferably arranged outside of the settlements in open spaces where there is no risk of later conversion. Examples are arable land and orchards. Such arrangements are also referred to as "energy fields". If the energy fields comprise several differently designed earth collectors, for example earth collectors with pipes of different lengths or different diameters, or several groups with a different number of earth collectors, these are interconnected via distributors. The distributors are used to hydraulically balance differently designed geothermal collectors or groups of geothermal collectors so that the respective geothermal collectors are flowed through evenly and evenly extract energy from the ground.
  • Manholes For use in energy fields, there are plastic distribution manholes that have shut-off and control valves, connections that lead out through the manhole wall and a manhole cover at the upper end that is roughly flush with the surface of the earth. Manholes are expensive, interfere with the agricultural processing of fields, for example, and are easily damaged by agricultural machines.
  • the EP 2 957 841 A1 describes a geothermal heat cycle in which several geothermal probes are used to increase the heat output that can be extracted from the ground.
  • the geothermal probes should be operated in parallel or in series, whereby the series connection is considered to be thermally advantageous because of the longer residence time of the liquid in the geothermal probes. The negative influence on the resulting increasing pressure loss should not be discussed at this point.
  • the geothermal probes are arranged in vertical boreholes and up to 100 m deep in the ground. Above the surface of the earth, the upper ends of the geothermal probes are connected to a pump and a heat exchanger via pipes.
  • the invention is based on the object of providing an arrangement of geothermal collectors for large-scale systems in the cold use of local heat, which does not require a distributor or has a significantly reduced number of distributors.
  • the inventive arrangement of geothermal collectors for large systems in cold local heating use comprises a first group of geothermal collectors, each of which is connected on the flow side via a first flow-side branch to a first common flow line and on the return side via a first return-side branch to a first common return line.
  • the first common flow line, the ground collectors including their connections with the first flow-side branches and the first return-side branches and the first common return line are designed in such a way that for each ground collector the sum of the pressure losses for the flow (i.) Of the first common flow line from its flow-side end up to the first flow-side branch to this ground collector, (ii.) for the flow through this ground collector and its connections with the first flow-side branch and the first return-side branch and (iii.) for the flow through the first common return line from the first return-side branch to this ground collector is the same size up to its return-side end.
  • geothermal collectors which, including their connections to the first flow-side branch and the first return-side branch, have the same pressure loss.
  • geothermal collectors which, including their connections to the first flow-side branches and the first return-side branches, are of identical design.
  • geothermal collectors the pipes of which have matching lengths and inside diameters, and connections (for example pipe connectors or hose connectors and, if applicable, connecting lines) which have matching inside diameters and lengths.
  • the invention uses a first common feed line and a first common return line. Each ground collector has a flow-side and a return-side connection.
  • the flow-side connection is connected to the first common flow line via a first flow-side branch.
  • the return-side connection is connected to the first common return line via a first return-side branch.
  • the arrangement is designed so that the sums of the pressure losses in the sections of the first common flow line and the first common return line, through which the heat transfer medium flows before and after flowing through any geothermal collector, are equal. Since the ground collectors including their connections with the first flow-side branches and the first return-side branches have the same pressure losses and the pressure losses of the first common supply and return lines are the same, the pressure losses for each ground collector are the same. This ensures that all ground collectors are flowed through evenly and evenly extract energy from the ground.
  • Hydraulic balancing of the ground collectors is therefore not necessary and the arrangement does not require a distributor.
  • a similar arrangement is known under the designation "Tichelmann system (Tichelmann pipe guide)", in which pipes from the boiler or from the solar system to the radiators and the boiler or fed back to the solar system in such a way that the sum of the lengths of the flow line and return line are roughly the same for each radiator.
  • radiators adapted to different room sizes and the heating of several floors prevent ideal hydraulic balancing.
  • This system has so far not been used for the arrangement of geothermal collectors in energy fields.
  • ideal hydraulic balancing is possible, since the pressure losses of the geothermal collectors including their connections with the first branches on the flow side and the first branches on the return side can be made the same.
  • the arrangement has no distribution shafts.
  • only one section of the first common flow line having the first flow-side end and only one section of the first common return line having the return-side end is led out of the ground, for example out of the surface of the earth or below the surface of the earth into a building.
  • the remaining part of the arrangement is arranged in the ground, preferably at least 0.5 m below the surface of the ground.
  • the first flow and return lines have the same internal cross-sections and is the sum of the lengths of the first common flow line from its flow-side (facing the outlet for the heat transfer medium of the heat pump) to the first flow-side branch to a specific ground collector and the first common return line from the first return-side branch to this ground collector to its return-side (the inlet for the heat carrier of the heat pump facing) end of the same length. This ensures that each liquid particle of the heat transfer medium that flows through any geothermal collector is subjected to the same overall conditions when it flows through the first common supply line and the first common return line.
  • the heat transfer medium flows in the flow line up to the first flow-side branch fast and behind the first return-side branch in the first common return line comparatively slowly and faster from branch to branch.
  • each liquid particle covers the same distance at the same speed, regardless of which collector it flows through.
  • the common flow and return lines have the same first internal cross-sections and the ground collectors including their connections with the first flow-side branches and the first return-side branches, the pressure losses for each ground collector are the same, so that all the ground collectors are flowed through evenly.
  • the flow lines and the return lines have a circular cross-section with matching first internal diameters (nominal values).
  • first internal diameters nominal values
  • the internal cross-section of the first common flow line and the first common return line is larger than the internal cross-section of the pipes of the ground collectors.
  • the pipes of the geothermal collectors have a circular cross-section with matching internal diameters.
  • the first flow line and the first return line are designed in such a way that for each ground collector the pressure losses of the part of the first common flow line arranged upstream of the ground collector and of the part of the first common return line arranged downstream of the same ground collector in the direction of flow are significantly lower than Pressure loss of the same ground collector.
  • "Much less” means a pressure loss of a maximum of 50%, preferably a maximum of 40%, preferably a maximum of 30%, preferably a maximum of 20%, preferably a maximum of 10%, preferably a maximum of 5% of the pressure loss of the geothermal collector through which the gas flows. This ensures that the pressure losses for each ground collector coincide essentially independently of the dimensioning of the flow line and the return line and the flow through all ground collectors is uniform.
  • the first common flow line and the first common return line have an inside diameter of 40.8 mm or less, or more if the first group comprises up to twelve ground collectors, and from 51.4 mm or less or more if the first group comprises 13 to 16 ground collectors.
  • the pressure losses in the first common supply line and in the first common return line are significantly lower than the pressure losses in the respective ground collector.
  • the hydraulic balancing primarily depends on the uniform design of the geothermal collectors.
  • a second group comprises several first groups with the same pressure losses, each of which is connected on the flow side via a second flow-side branch to a second common flow line and on the return side via a second return-side branch to a second common return line, the second common return line
  • the flow line and the second common return line are designed so that for each first group the sum of the pressure losses for the flow through the second common flow line from its flow-side end to the second flow-side branch to this first group and the first common return line from the second return-side branch this first group are the same size up to their return end.
  • the first groups with the same pressure losses are identically designed first groups.
  • first groups denote first groups which match with regard to the properties specified in claim 1 and the number of geothermal collectors.
  • the end of this flow line facing the outlet for the heat carrier of the heat pump is designated with the flow-side end of the second common flow line and the end of this return line facing the inlet for the heat carrier of the heat pump is designated with the return-side end of the second common return line.
  • several first groups are interconnected to form a second group. The pressure losses when flowing through each first group including the associated sections of the second common supply line and the second common return line are the same.
  • the ground collectors of all the first groups are uniformly traversed by the heat transfer medium and energy is evenly withdrawn from the ground without a hydraulic one Adjustment by means of distributors is required. This type of design enables flexible distribution of the geothermal collectors over larger energy fields.
  • the arrangement has no distribution shafts. According to a further embodiment, only a section of the second common flow line having the flow-side end and only a section of the second common return line having the return-side end is led out of the ground, for example out of the surface of the earth or below the surface of the earth into a building. The remaining part of the arrangement is arranged in the ground, preferably at least 0.5 m below the surface of the ground.
  • the second common flow line and the second common return line have the same second internal cross-sections (same second internal diameter for circular cross-sections) and for each first group is the sum of the lengths of the second common flow line from its flow-side end to the second flow-side branch to this Group and the first common return line from the second return-side branch to this first group to its return-side end of the same size. This ensures that the pressure losses are always the same, regardless of which first group the heat transfer medium flows through.
  • the internal cross-section of the second common feed line and the second common return line is larger than the internal cross-section of the first common feed line and the second common feed line.
  • the second common flow line and the second common return line are designed in such a way that the pressure losses when flowing through one in the flow direction upstream of any first group arranged part of the further common supply line and a part of the second common return line arranged downstream of the same first group in the direction of flow is significantly less than the flow loss when flowing through the same first group.
  • "Much less” means a pressure loss of a maximum of 20%, preferably a maximum of 40%, preferably a maximum of 30%, preferably a maximum of 20%, preferably a maximum of 10%, preferably a maximum of 5% of the pressure loss when flowing through the first group .
  • first groups which comprise a maximum of 16 ground collectors, which have a pipe with a maximum of 20.4 mm or less or more internal diameter
  • first common supply line and the first common return line have an internal diameter of maximum 51.4 mm or have less or more.
  • the inner diameter of the second common supply line and the second common return line is 115 mm or less or more when the second group includes up to ten first groups.
  • the pressure losses in the second common supply lines and the second common return lines are significantly lower than in the first groups.
  • an n-th group comprises several (n-1) -th groups with the same pressure loss, each on the flow side via an n-th flow-side branch with an n-th common flow line and on the return side via an n-th return-side Junction are connected to an n-th common return line, the n-th flow line and the n-th return line being designed so that for each (n-1) -th group the sum of the pressure losses for the flow through the n-th common Flow line from its flow-side end to the n-th flow-side branch to this (n-1) -th group and the n-th common return line from the n-th return-side branch to this (n-1) -th group to its return side End is the same.
  • n is an integer equal to or greater than two. In this embodiment, it is ensured that the pressure loss for the flow through each (n-1) -th group including the associated sections of the n-th common feed line and the n-th common return line is the same. As a result, all ground collectors are flowed through evenly and energy is extracted evenly from the ground without the need for distributors.
  • the arrangement has no distribution shafts.
  • only a section of the n-th common flow line having the flow-side end and only a section of the n-th common return line having the return-side end is led out of the ground, for example from the surface of the earth or below the surface of the earth into a building.
  • the remaining part of the arrangement is arranged in the ground, preferably at least 0.5 m below the surface of the ground.
  • the (n-1) th groups are of identical design.
  • the identically designed (n-1) th groups have the same number of ground collectors, the same ground collectors, the same connections between the ground collectors and the first flow-side branches, the same connections between the ground collectors and the first return-side branches, the same first flow lines and the same first return lines.
  • the n-th common flow line and the n-th common return line have the same n-th internal cross-sections (same n-th internal diameter for circular cross-sections) and are the sum of the lengths of the for each (n-1) -th group n-th common flow line from its flow-side end to the n-th flow-side branch to this group and the n-th common return line from the n-th return-side branch to this (n-1) -th group to its return-side end of the same size .
  • the internal cross-section of the n-th common supply line and the n-th common return line is larger than the internal cross-section of the (n-1) -th common supply line and the (n-1) -th common return line.
  • the n-th common supply line and the n-th common return line are designed so that the sum of the pressure losses in the part of the n upstream of the same group in the flow direction for the flow through any (n-1) -th group -th flow line and the part of the n-th common return line downstream of the same group are significantly lower than the pressure loss when flowing through the (n-1) -th group.
  • "Much less” means a pressure loss of a maximum of 50%, preferably a maximum of 40%, preferably a maximum of 30%, preferably a maximum of 20%, preferably a maximum of 10%, preferably a maximum of 5% of the pressure loss when flowing through the (n- 1) -th group understood.
  • all the ground collectors of the arrangement are designed in the same way, so that a group comprising only these collectors can do without a distributor.
  • there is at least one differently designed ground collectors so that a group comprising these ground collectors includes at least one distributor.
  • the (n-1) th groups are of identical design, so that an n-th group exclusively comprising these (n-1) th groups can do without a distributor.
  • the nth group comprises, in addition to identically designed (n-1) th groups, at least one unequally designed (n-1) th group. This can be interconnected with the other (n-1) th groups via distributors.
  • the geothermal collectors each have a tube running in a loop, spiral or meandering shape in one plane.
  • the tube is arranged on at least one support structure, preferably on slats or on a slatted frame.
  • the spiral tube has in a central section of the ground collector straight and parallel first sections and at the ends of the ground collector curved and parallel second sections.
  • the straight first sections of the tubes are fixed on at least one first slat extending perpendicular to these sections of the tubes and the curved second sections are fixed on second slats running in the direction of the straight sections.
  • the tube is a plastic tube.
  • the pipe is made of a metal-plastic composite pipe or of metal.
  • the slats are made of wood or of plastic or of metal or of composite material.
  • the tube is fastened to the slats by means of staples, clips or other fastening means.
  • the expansion of the geothermal collectors in the direction of the straight sections is greater than in the direction perpendicular thereto.
  • the extension of the ground collectors in the direction of the straight sections (longitudinal direction) is a maximum of 25 m and / or in the direction perpendicular thereto (transverse direction) a maximum of 5 m. B. 10 mx 2 m or 5 mx 2 m.
  • This dimensioning of the geothermal collectors is advantageous for transport on a truck. This is advantageous for the production of the geothermal collectors under favorable conditions in a workshop or factory equipped for this purpose and for bringing the finished geothermal collectors to the Place of laying by truck.
  • the geothermal collectors with a size of 2 ⁇ 10 m have a pipe 25 ⁇ 2.3 mm and 106 m long.
  • the geothermal collectors of size 2 ⁇ 5 m have a pipe 20 ⁇ 2.0 mm and 72 m in length.
  • the ground collector is designed and / or laid in the ground, as described in one of the following documents: EP 244 017 A1 , DE 10 2009 005 540 B3 , EP 2 241 850 B1 , EP 2 572 145 B1 , DE 10 2011 111 704 B3 .
  • EP 244 017 A1 DE 10 2009 005 540 B3
  • EP 2 241 850 B1 EP 2 572 145 B1
  • DE 10 2011 111 704 B3 DE 10 2011 111 704 B3 .
  • At least one of the ground collectors is composed of several smaller collector elements which, when put together, correspond to a single ground collector.
  • a ground collector with a size of 2 ⁇ 10 m is composed of two collector elements of size 2 ⁇ 5 m, whereby the same pipe is used for the collector elements as for a single ground collector that they replace (e.g. 25 ⁇ 2, 3 mm).
  • the arrangement comprises horizontally laid ground collectors.
  • the horizontal arrangement of the geothermal collectors is preferably used when laying in unstable floors.
  • the arrangement comprises vertically laid ground collector modules.
  • the excavated earth for laying the geothermal collectors can be reduced considerably. Vertical installation of the geothermal collectors is possible, especially in stable floors.
  • the geothermal collectors are laid horizontally or vertically in several layers one above the other. This can reduce the effort required to lay a certain number of geothermal collectors.
  • the arrangement comprises a first group of several ground collectors arranged one behind the other in a certain direction and laid in the same direction, sections of the first common flow line and the first common return line adjoining the flow-side end and the return-side end.
  • the ground collectors of the first group are arranged one behind the other in their transverse direction or are arranged one behind the other in their longitudinal direction.
  • the arrangement comprises a second group of several first groups arranged one behind the other in a certain horizontal direction and laid in the same direction, adjoining the flow-side end and the return-side end sections of the second common flow line and the second common return line.
  • the arrangement comprises an n-th group of a plurality of (n-1) -th groups arranged one behind the other in a specific horizontal direction and laid in the same direction and arranged at the forward end and the return end of the n-th common sections Flow lines and nth common return lines.
  • n is an integer equal to or greater than two.
  • the n-th common feed lines and n-th common return lines run perpendicular to the (n-1) -th common feed lines and (n-1) -th common return lines. This favors a particularly space-saving arrangement with short cable paths.
  • the ground collectors are under a field (z. B. a field) and / or under a green area (z. B. a park, orchard, soccer field, etc.) and / or under a building (z. B. a Warehouse) and / or other paved surfaces (e.g. parking lots, sports fields with hard court surface) and / or in water surfaces (e.g. ponds, lakes, streams and rivers).
  • a field z. B. a field
  • a green area z. B. a park, orchard, soccer field, etc.
  • a building z. B. a Warehouse
  • paved surfaces e.g. parking lots, sports fields with hard court surface
  • water surfaces e.g. ponds, lakes, streams and rivers.
  • the geothermal collectors are arranged under a built-up area.
  • a built-up area is an area underneath a building, parking lot, sports field with a hard court surface or street where natural regeneration through heat from the environment is completely or essentially prevented.
  • the geothermal collectors are partially arranged under an open area and partially under a built-up area.
  • An open area is a field, a green area, an unpaved or essentially unpaved or built-up area, in which natural regeneration takes place through heat brought into the ground from the environment, in particular from rain, outside air and sun.
  • geothermal collectors in the arrangement are under a built-up area, while the other part of the geothermal collectors is under an open area, so that it undergoes natural regeneration through sun, rain and outside temperature. Since the geothermal collectors in the arrangement according to the invention are hydraulically connected to one another, the geothermal collectors under the built-up area also participate in the regeneration of the geothermal collectors under the open area through environmental influences in summer. In return, the arrangement benefits in winter from the heat stored under built-up areas, for example under a building, since the ground under the building is not exposed to the same degree of external climatic conditions as the geothermal collectors under the open space.
  • Source temperatures to be expected ie the temperatures of the ground in which the geothermal collectors are laid, are to be expected with such an arrangement in winter as higher than with laying exclusively under an open area.
  • an additional area under built-up areas will be developed for the arrangement of the geothermal collectors, which is not considered usable in current guidelines due to the lack of natural regeneration.
  • geothermal heating comprises an arrangement of geothermal collectors according to one of the embodiments described above, at least one heat pump and several heat transfer systems to the rooms to be air-conditioned.
  • the heat transfer systems comprise one or more of the following devices: radiators, surface heating and cooling (wall, ceiling and / or floor heating), heating and / or cooling registers of ventilation systems.
  • the heating and cooling devices are arranged in one or in several buildings.
  • the geothermal heating comprises a switching device which feeds the heat transfer medium past the heat pump directly into the heating devices in order to cool the building by means of the heat transfer medium when the outside temperature is elevated.
  • the increased outside temperatures are preferably above the comfort temperature (21 ° to 23 ° C). If the temperature of the heat transfer medium is regularly 12 to 15 ° in August, the heat transfer medium can be used to cool the building.
  • the heat transfer systems are preferably floor heating systems and / or other surface heating or cooling systems. According to a further embodiment, this also includes heating registers in ventilation and air conditioning systems that are used for cooling. According to a further embodiment, the cooling takes place via a separate cooling register.
  • a ground collector 1 comprises a pipe 2 running spirally in a plane with a flow-side connection 3 and a return-side connection 4.
  • the pipe 2 is straight in a central section 5 of the ground collector 1 and first sections 6 running parallel to one another and second sections 7 which are curved and parallel to one another at the ends of the earth collector 1.
  • the tube 2 is fixed on first slats 8 extending perpendicular to the rectilinear sections.
  • the tube 2 is fixed on a second slat 9 running in the direction of the straight first sections 5.
  • the longitudinal direction of the ground collector 1 is in the direction of the rectilinear sections 5.
  • the extent of the geothermal collector 1 is smaller. For example, its main dimensions are 2 m x 10 m or 2 m x 5 m.
  • a first group 10 comprises a plurality of identically designed ground collectors 1.
  • the lengths of the tubes 2, as well as their inner cross-sections, are the same for all ground collectors 1.
  • the tubes are preferably 2 circular tubes with the same inner diameter.
  • the first group 10 comprises a first common feed line 11 and a first common return line 12, which have the same internal cross-sections. When designed as a circular tube, the inside diameters match.
  • each ground collector 1 is connected to the first common flow line 11 via a first flow-side branch 13.
  • the return-side connection 4 of each ground collector 1 is connected to the first common return line 12 via a first return-side branch 14.
  • the arrangement is designed so that the ground collector 1, which is connected to the first flow-side branch 13, which is closest to the flow-side end 15 of the first common flow line 11, is connected to the first return-side branch 14, which is farthest away from end 16 on the return side of the first common return line 12.
  • each ground collector 1 participates in the heat transfer to the heat transfer medium in the first group 10 to the same extent.
  • the ground collectors 1 are arranged one behind the other in the transverse direction.
  • the first common flow line 11 extends from its flow-side end 15 and the first common return line 12 extends from its return-side end 16 in the same direction.
  • a second group 17 comprises several identically designed first groups 10. All ground collectors 1 of the first groups 10 are identically designed. Each first group 10 has the same number of ground collectors 1. The arrangement and the internal cross-section of the first common supply line 11, as well as the arrangement and the internal cross-section of the first common return line 12, are the same in all of the first groups 10. The ground collectors 1 in all first groups 10 are also connected in the same way via first flow-side branches 13 and first return-side branches 14 to the first common supply lines 11 and the first common return lines 12.
  • the first common flow lines 11 are connected via second flow-side branches 18 to a second common flow line 19 and the first common return lines 12 and via second return-side branches 20 to a second common return line 21.
  • Adjacent to its flow-side end 22 extends the second common flow line 19 and adjacent to its return-side end 23, the second common return line 21 extends perpendicular to the first common flow lines 11 and the first common return lines 12 of the first groups.
  • connection of the first groups 10 to the second common flow line 19 and the second common return line 21 is designed so that each flow particle travels the same path when flowing through the second group 17, regardless of which first group 10 it flows through. This promotes a uniform heat transfer to the ground collectors 1.
  • a third group 24 comprises several second groups 17.
  • Each second group 17 consists of the same number of identically configured first groups 10.
  • the second groups 17 are each connected to the third common flow line 26 via a third flow-side branch 25 and via a third return-side branch 27 connected to the third common return line 28.
  • the connection of the second groups 17 to the third common flow line 26 and the third common return line 28 is selected so that each flow particle travels the same path when flowing through the third group 24, regardless of which second group 17, which first group 10 and which ground collector 1 flows through the first particle. This favors a uniform heat transfer to each ground collector 1.
  • Fig. 5 two identically designed ground collectors 1 are arranged in different layers 29 under a field 30. This can reduce the laying effort.
  • a plurality of ground collectors 1 of the same type is arranged in two layers 29 one above the other under a field 30.
  • the ground collectors 1 can be connected together in a single first group 10 or can be connected together in a plurality of superordinate and subordinate groups 17, 23.
  • a plurality of geothermal collectors 1 of the same type is arranged vertically under a field 30.
  • slots or trenches can be drawn, which are filled with soil again after the ground collectors 1 have been inserted.
  • the ground collectors 1 can be connected together in a single first group 10 or in a plurality of superordinate and subordinate groups 17, 23.
  • FIG. 8 Vertically laid ground collectors 1 are connected to one another in four first groups 10 each consisting of three ground collectors 1. The four first groups 10 are in turn connected to one another to form a superordinate second group 17.
  • the Figures 9 to 11 show different arrangements of a first group 10 of geothermal collectors 1 under a built-up area 31 (hatched) and under one or more open areas 32 (not hatched). Depending on the structural and local climatic conditions, different areas can be used for near-surface geothermal energy.

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EP19218755.7A 2019-12-20 2019-12-20 Agencement de collecteurs géothermiques pour grandes installations dans l'utilisation de froid urbain Withdrawn EP3839372A1 (fr)

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Citations (10)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
EP0244017A1 (fr) 1986-04-29 1987-11-04 Koninklijke Philips Electronics N.V. Dispositif de contact électrique et méthode pour sa fabrication
US5025634A (en) * 1989-04-25 1991-06-25 Dressler William E Heating and cooling apparatus
US5461876A (en) * 1994-06-29 1995-10-31 Dressler; William E. Combined ambient-air and earth exchange heat pump system
DE102009005540B3 (de) 2009-01-20 2010-08-05 TechConcept GbR (vertretungsberechtigte Gesellschafter: Hans-Ulrich Karsch, 96271 Grub und Harry Steinhäuser, 96191 Viereth-Trunstadt) Erdkollektorvorrichtung und Montagevorrichtung und Verfahren zur Herstellung einer Erdkollektorvorrichtung
KR101011130B1 (ko) * 2008-06-11 2011-01-28 벽산건설 주식회사 지중 열교환기
DE102011013275A1 (de) * 2010-03-05 2011-09-08 Wq-Tec Ag Verfahren zur Errichtung eines Erdkollektors
EP2241850B1 (fr) 2006-12-22 2012-02-22 WQ-Tec AG Procédé d'installation d'un module de collecteur terrestre
DE102011111704B3 (de) 2011-06-21 2012-10-11 Wq-Tec Ag Erdkollektorsystem, Verfahren zur Steuerung und Verfahren zur Errichtung
EP2957841A1 (fr) 2007-09-08 2015-12-23 Dynamic Blue Holding GmbH Circuit d'échangeur d'énergie géothermique
EP2572145B1 (fr) 2010-05-18 2018-01-10 WQ-Tec AG Collecteur géothermique, système et procédé pour installer un collecteur géothermique

Patent Citations (10)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
EP0244017A1 (fr) 1986-04-29 1987-11-04 Koninklijke Philips Electronics N.V. Dispositif de contact électrique et méthode pour sa fabrication
US5025634A (en) * 1989-04-25 1991-06-25 Dressler William E Heating and cooling apparatus
US5461876A (en) * 1994-06-29 1995-10-31 Dressler; William E. Combined ambient-air and earth exchange heat pump system
EP2241850B1 (fr) 2006-12-22 2012-02-22 WQ-Tec AG Procédé d'installation d'un module de collecteur terrestre
EP2957841A1 (fr) 2007-09-08 2015-12-23 Dynamic Blue Holding GmbH Circuit d'échangeur d'énergie géothermique
KR101011130B1 (ko) * 2008-06-11 2011-01-28 벽산건설 주식회사 지중 열교환기
DE102009005540B3 (de) 2009-01-20 2010-08-05 TechConcept GbR (vertretungsberechtigte Gesellschafter: Hans-Ulrich Karsch, 96271 Grub und Harry Steinhäuser, 96191 Viereth-Trunstadt) Erdkollektorvorrichtung und Montagevorrichtung und Verfahren zur Herstellung einer Erdkollektorvorrichtung
DE102011013275A1 (de) * 2010-03-05 2011-09-08 Wq-Tec Ag Verfahren zur Errichtung eines Erdkollektors
EP2572145B1 (fr) 2010-05-18 2018-01-10 WQ-Tec AG Collecteur géothermique, système et procédé pour installer un collecteur géothermique
DE102011111704B3 (de) 2011-06-21 2012-10-11 Wq-Tec Ag Erdkollektorsystem, Verfahren zur Steuerung und Verfahren zur Errichtung

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